Rotary axis cable wiring structure

ABSTRACT

To provide a rotary axis cable wiring structure and a robot having higher usability at the time of assembly and increased reliability as to whether or not cables are properly disposed. A rotary axis cable wiring structure includes a fixed member and a movable member which are rotatable relatively, a cylindrical hollow pipe member disposed between the fixed member and the movable member so as to be rotatable with respect to the movable member, a plurality of cable bundles passed from one of the fixed member and the movable member to the other through the hollow pipe member, first cable fixing means for fixing the cable bundles to the fixed member, and second cable fixing means for fixing the cable bundles to the movable member. Each of the cable bundles includes a plurality of cables, and a cable bundling member having an outer diameter smaller than an inner diameter of the hollow pipe member and bundling the plurality of cables in a state where mutual relative arrangement is maintained.

This application is based on and claims the benefit of priority fromJapanese Patent Application No. 2017-150531, filed on 3 Aug. 2017, thecontent of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a rotary axis cable wiring structure inwhich a cable is inserted through a cylindrical rotary axis part, and arobot having the rotary axis cable wiring structure.

Related Art

Some conventional industrial robots include a hollow pipe to protect acable disposed from one to the other of members rotating relatively(refer to, for example, Patent Documents 1 and 2). Such an industrialrobot requires more cables passed through the inside in order to dealwith vision, sensors and the like.

-   Patent Document 1: Japanese Unexamined Patent Application,    Publication No. 2015-168037-   Patent Document 2: Japanese Unexamined Patent Application,    Publication No. 2003-305684

SUMMARY OF THE INVENTION

In some cases, a whole cable assembly in which many cables are bundledby a cable clamp is not able to be passed through a hollow pipe togetherwith the cable clamp because the hollow pipe has a small diameter or thefilling degree of such cables is high.

The cables need to be fixed after being passed through the hollow pipe.In this case, the cables need to be fixed so as not to intersect (cross)mutually inside the hollow pipe. However, in some cases where thefilling degree of such cables in the hollow pipe is high, even checkingmay be difficult. As a result, problems arise that assembly takes timeand that the reliability as to whether or not the cables are disposedproperly is low.

An object of the present invention is to provide a rotary axis cablewiring structure and a robot having higher usability at the time ofassembly and increased reliability as to whether or not cables aredisposed properly.

(1) The rotary axis cable wiring structure (for example, a rotary axiscable wiring structure 2 described below) according to the presentinvention includes a first member (for example, a fixed member 3described below) and a second member (for example, a movable member 4described below) rotatable respectively, a cylindrical rotary axis part(for example, a hollow pipe member 5 described below) disposed betweenthe first member and the second member so as to be rotatable withrespect to at least one of the first member and the second member, oneor a plurality of cable bundles (for example, cable bundles 6 describedbelow) passed from one of the first member and the second member to theother through the rotary axis part, first cable fixing means (forexample, first cable fixing means 7 described below) for fixing thecable bundles to the first member, and second cable fixing means (forexample, second cable fixing means 8 described below) for fixing thecable bundles to the second member. Each of the cable bundles includes aplurality of cables (for example, cables 60 described below), and acable bundling member (for example, a cable bundling member 61 describedbelow) having an outer diameter smaller than an inner diameter of therotary axis part and bundling the plurality of cables in a state wheremutual relative arrangement is maintained.

(2) In the rotary axis cable wiring structure according to (1), withrespect to each of the cables, a length (for example, a length L1described below) from a portion bundled by the cable bundling member toa connector (for example, a connector 60 a described below) provided atan end portion may be longer than a length (for example, a length L2described below) of the rotary axis part in an axial direction.

(3) In the rotary axis cable wiring structure according to (1) or (2),each of the cable bundles may include two of the cable bundling membersat spaced positions, and the plurality of cables may be disposedmutually in parallel in a section interposed between the cable bundlingmembers in a predetermined state of the first member and the secondmember not rotated relatively.

(4) In the rotary axis cable wiring structure according to any one of(1) to (3), the predetermined state of the first member and the secondmember not rotated relatively may correspond to a state of the rotaryaxis part positioned at a reference angle, and the rotary axis part mayhave allowable maximum twisting angles equal in both normal and reverserotating directions from the reference angle.

(5) In the rotary axis cable wiring structure according to any one of(1) to (4), each of the cable bundles may be a cable kit fixed inadvance to one of the first cable fixing means and the second cablefixing means.

(6) In the rotary axis cable wiring structure according to any one of(1) to (5), the same member may serve as each of the cable bundlingmembers.

(7) In the rotary axis cable wiring structure according to any one of(1) to (6), the cable bundling member may be a plate member having asubstantially same width as a width of each of the cable bundles, andmay have a structure capable of being fixed by a bolt to the first cablefixing means or the second cable fixing means.

(8) In the rotary axis cable wiring structure of any one of (1) to (6),the cable bundling member may be a tape member.

(9) The rotary axis cable wiring structure according to any one of (1)to (8) may further include means for identifying the cables.

(10) The robot (for example, a robot 1 described below) according to thepresent invention includes the rotary axis cable wiring structureaccording to any one of (1) to (9).

The present invention is able to provide a rotary axis cable wiringstructure and a robot having higher usability at the time of assemblyand increased reliability as to whether or not cables are disposedproperly.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram illustrating a rotary axis cable wiringstructure of a robot according to one embodiment of the presentinvention.

FIG. 2 is a schematic diagram illustrating a cable bundle constitutingthe rotary axis cable wiring structure shown in FIG. 1.

FIG. 3 is a cross-sectional view of the rotary axis cable wiringstructure cut along a line III-III shown in FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

One embodiment of the present invention will be described below indetail with reference to FIG. 1 and FIG. 2. FIG. 1 is a schematicdiagram illustrating a rotary axis cable wiring structure 2 of a robot1. FIG. 2 is a schematic diagram illustrating a cable bundle 6constituting the rotary axis cable wiring structure 2 shown in FIG. 1.

As shown in FIG. 1, the rotary axis cable wiring structure 2 of therobot 1 is configured to protect a plurality of cables 60 disposed fromone to the other of members 3, 4 rotating relatively, so as to preventdamage such as disconnection caused by torsion (twisting).

Specifically, the rotary axis cable wiring structure 2 includes a fixedmember (first member) 3, a movable member (second member) 4, a hollowpipe member (rotary axis part) 5, a plurality of the cable bundles 6,first cable fixing means 7, and second cable fixing means 8.

The fixed member 3, which is a member having an internal space, supportsand fixes one end of the hollow pipe member 5 so as to communicate withthe hollow pipe member 5. In the fixed member 3, the first cable fixingmeans 7 fixes the cables 60 passed through the hollow pipe member 5 fromthe movable member 4.

The movable member 4, which is a member having an internal space,rotatably supports the other end of the hollow pipe member 5 so as tocommunicate with the hollow pipe member 5. In the movable member 4, thesecond cable fixing means 8 fixes the cables 60 passed through thehollow pipe member 5 to the fixed member 3.

The hollow pipe member 5, which is a cylindrical member constituting awrist of the robot 1, communicates with the fixed member 3 so that theone end of the hollow pipe member 5 is supported and fixed to the fixedmember 3, and also communicates with the movable member 4 so that theother end of the hollow pipe member 5 is rotatably supported by themovable member 4.

The cable bundles 6 are passed from the movable member 4 through thehollow pipe member 5 to the fixed member 3. As shown in FIG. 1 and FIG.2, each of the cable bundles 6 includes the plurality of cables 60 andtwo cable bundling members 61.

Each of the plurality of cables 60 has a connector 60 a at the endportion thereof. The plurality of cables 60 are bundled by the two cablebundling members 61 in a state in which the mutual relative arrangementof the cable bundling members 61 is maintained. A length L1, which isthe length from the portion bundled by the cable bundling member 61closer to the connector 60 a to the connector 60 a provided at the endportion, is longer than a length L2 of the hollow pipe member 5 in theaxial direction. The plurality of cables 60 are disposed mutually inparallel in the section interposed between the cable bundling members61, in a predetermined state (initial reference state) in which thefixed member 3 and the movable member 4 are not rotated relatively.

The plurality of cables 60 are configured so that the angle in onedirection by which the cables are twisted maximally is equal to theangle in the other direction by which the cables are twisted maximally.Therefore, with respect to the fixed member 3 and the movable member 4,the angle in one direction by which the fixed member 3 and the movablemember 4 are rotatable from the initial state in which the fixed member3 and the movable member 4 are not rotated relatively is equal to theangle in the other direction by which the fixed member 3 and the movablemember 4 are rotatable from the initial state. Accordingly, thepredetermined state (the initial reference state) in which the fixedmember 3 and the movable member 4 are not rotated relatively means thestate in which the hollow pipe member 5 is positioned at a referenceangle. In this case, the hollow pipe member 5 has the allowable maximumtwisting angles equal in both normal and reverse rotating directionsfrom the reference angle.

The two cable bundling members 61 bundle the plurality of cables 60 atspaced positions in a state in which the mutual relative arrangement ofthe cable bundling members 61 is maintained. The cable bundling members61, each of which has an outer diameter smaller than the hollow pipemember 5, are able to be passed through the hollow pipe member 5.

Specifically, each of the cable bundling members 61 is a plate memberhaving a width W2 which is slightly larger than a width W1 of the cablebundle 6 and substantially equal to the width W1 of the cable bundle 6,and has a structure capable of being fixed by a bolt to the first cablefixing means 7 or the second cable fixing means 8. The same memberserves as each of the plurality of cable bundling members 61constituting each of the cable bundles 6.

Each of the cable bundles 6 is a cable kit fixed in advance to thesecond cable fixing means 8 corresponding to the one which is positionedcloser to the base end portion of the cable bundles 6 (positioned in theopposite side to the connector 60 a) in the first cable fixing means 7and the second cable fixing means 8. That is, the cable bundling member61 is fixed in advance to the second cable fixing means 8, and the cablebundling member 61 is to be fixed to the first cable fixing means 7 in asubsequent operation. In this case, the first cable fixing means 7 andthe second cable fixing means 8 need to have a structure that isdetachable from the fixed member 3 and the movable member 4,respectively.

A description is given with reference to FIG. 1 again. The first cablefixing means 7, which is provided inside the fixed member 3, issubjected to fixing of the cable bundling member 61 with a bolt, therebyfixing all of the cable bundles 6 to the fixed member 3. That is, thefirst cable fixing means 7 fixes the cables 60 in the vicinity of thehollow pipe member 5, so that, when the fixed member 3 and the movablemember 4 are rotated relatively, the cables 60 do not move relatively tothe first cable fixing means 7 in the longitudinal direction of thecables 60 or in the rotation direction of the cables 60 being twisted.

The second cable fixing means 8, which is provided inside the movablemember 4, is subjected to fixing of the cable bundling member 61 with abolt, thereby fixing all of the cable bundles 6 to the movable member 4.That is, the second cable fixing means 8 fixes the cables 60 in thevicinity of the hollow pipe member 5, so that, when the fixed member 3and the movable member 4 are rotated relatively, the cables 60 do notmove relatively to the second cable fixing means 8 in the longitudinaldirection of the cables 60 or in the rotation direction of the cables 60being twisted.

One example of the inside of the hollow pipe member 5 is described belowwith reference to FIG. 3. FIG. 3 is a cross-sectional view of the cablearrangement 2 cut along a line III-III shown in FIG. 1.

As shown in FIG. 3, the plurality of cables 60 are disposed inside thehollow pipe member 5. In the case where the hollow pipe member 5, whichhas a hollow hole diameter (internal diameter) of 40 mm, houses four ofthe cables 60 each having a diameter of 9 mm, four of the cables 60 eachhaving a diameter of 8 mm, and four of the cables 60 each having adiameter of 6 mm, a ratio of the total cross-sectional area of thecables 60 to the cross-sectional area of the hollow hole is 54.3%. It isnoted that gaps are formed among the cables 60, and thus the ratio ofthe portion occupied by the cables 60 (the portion shown with hatching)to the cross-sectional area of the hollow hole (hollow hole occupancyratio) is 75.7%.

As described above, even when the occupancy ratio (filling degree) ofthe cables in the hollow pipe member 5 is high, the rotary axis cablewiring structure 2 of the robot 1 according to the present embodiment isable to provide higher usability at the time of assembly and increasedreliability as to whether or not the cables 60 are disposed properly.

Even in the case where the hollow hole occupancy ratio in thecross-sectional area of the hollow hole is high, the plurality of cables60 are passed through the hollow pipe member 5 so that the plurality ofcables 60 do not cross inside the hollow pipe member 5, and order inarrangement is ensured at the time of assembly even without checking indetail the arrangement of the many cables 60, whereby the usability ishigh and the reliability is also increased.

Since the length L1 of the cables 60 from the portion bundled by thecable bundling member 61 to the connector 60 a provided at the endportion is longer than the length L2 of the hollow pipe member 5 in theaxial direction, the connectors 60 a having a larger thickness than eachof the cables 60 is able to be passed through the hollow pipe member 5one by one. The connectors 60 a are passed through the hollow pipemember 5, enabling the passing of the cable bundle 6 through the hollowpipe member 5, whereby the usability is further improved.

The cable bundling member 61 is provided also to the side of the cablebundle 6 not passed through the hollow pipe member 5 (the side of themovable member 4), whereby the positional relation between the two cablebundling members 61 is defined and thus the usability is furtherimproved.

The hollow pipe member 5 has a certain reference angle (for example, 0°)and specifications adaptive to twisting by the maximum angles equal inthe clockwise direction and in the counterclockwise direction from thereference angle. The hollow pipe member 5 is configured so that thefixed member 3 and the movable member 4 are not rotated relatively whenthe hollow pipe member 5 is positioned at the reference angle. Thisprovides such a structure that the cables 60 are able to be wiredmutually in parallel under a state where the minimum stress acts on thecables 60, and that the maximum stress acts on the cables 60 at themaximum angles equal in the clockwise direction and in thecounterclockwise direction, thereby enabling the realization of longerlives in the cables 60.

Since each of the cable bundles 6 is a cable kit fixed in advance to thesecond cable fixing means 8 corresponding to the one which is positionedcloser to the base end portion of the cable bundle 6 (positioned in theopposite side to the connector 60 a) in the first cable fixing means 7and the second cable fixing means 8, the positional relation among thecables 60 of all of the cable bundles 6 is defined and thus theusability is further improved.

The same member serves as each of the cable bundling members 61 of eachof the cable bundles 6, thereby enabling reduction in cost andprevention of errors in assembling components.

A simple and unbulky plate member serves as each of the cable bundlingmembers 61, thereby enabling further improvement in usability andreduction in cost.

Although the embodiment of the present invention has been describedabove, the present invention is not limited to the above-describedembodiment. The most preferable effects produced by the presentinvention have been merely listed as the effects in the presentembodiment, and the effects according to the present invention are notlimited to those described in the present embodiment.

Although the case where the fixed member 3 fixed to the hollow pipemember 5 and the movable member 4 rotatable with respect to the hollowpipe member 5 are included as the relatively rotatable members has beendescribed in the above embodiment, the present invention is not limitedto the above case. In the present invention, another member rotatablewith respect to the hollow pipe member 5, instead of the fixed member 3,may be included as a relatively rotatable member.

Although the case where the plurality of cable bundles 6 are includedhas been described in the above embodiment, the present invention is notlimited to the case above. In the present invention, another case may beapplicable, where one cable bundle 6 is included.

Although the case where the plurality of cables 60 are bundled by thecable bundling members 61 each of which is a plate member has beendescribed in the above embodiment, the present invention is not limitedto the above case. In the present invention, another case may beapplicable, where the plurality of cables 60 are bundled by a cablebundling member which is a tape member, instead of the cable bundlingmember 61 or in addition to the cable bundling member 61. The cablebundling member, which is a tape member, may wind around a portionfurther separated from the hollow pipe member 5 than the first cablefixing means 7 or the second cable fixing means 8, or may directly windaround the portion of the plurality of cables 60 to be fixed on thefirst cable fixing means 7 or the second cable fixing means 8. In otherwords, it is necessary to wind and fix the non-movable portions of thecables 60. If the movable region is fixed, the cables 60 are restrainedin movement, which may result in early disconnection of the cables 60.

In the above-described embodiment, means for identifying the cables 60may be provided in the vicinity of the cable bundling member 61. Theplurality of cables 60 are passed through as the cable bundle 6 at thetime of assembly, and thus the positional relation of the cables 60 maynot be known. Provision of the means for identifying the cables 60solves such a problem.

Alternatively, the cable 60 may be configured with a plurality ofcables, for example, four cables including two cables in thelongitudinal direction of the cable bundling member 61 and two cables inthe thickness (height) direction of the cable bundling member 61. Insuch a case, the cable bundling member 61 is able to be checked as towhether each of the four cables constituting the cable 60 is positionedat the same phase in the direction of rotation (twisting of the cable60) with respect to the two cable bundling members 61, therebypreventing the cable 60 from being disposed in a slightly twisted statein the section interposed between the two cable bundling members 61. Inthis case, there is a possibility that twisting by one turn (360°) maynot be identified. However, it is not easy to fix to the cable bundlingmembers 61 the cable 60 intentionally twisted by one turn in such ashort section. Therefore, there is no problem as long as slight twistingis able to be prevented.

Although the hollow pipe member 5 in the above-described embodiment isconfigured to be rotatable with respect to at least one of the fixedmember 3 and the movable member 4 such that one end thereof is supportedby the fixed member 3 and the other end is supported by the movablemember 4, the invention is not limited to the above configuration. In anexample, the hollow pipe member 5 may be integrated with the fixedmember 3 or the movable member 4.

In the above-described embodiment, the first cable fixing means 7 fixesall of the cable bundles 6 to the fixed member 3. Alternatively, thefirst cable fixing means 7 may fix some of the cable bundles 6 to thefixed member 3. The second cable fixing means 8 fixes all of the cablebundles 6 to the movable member 4. Similarly, the second cable fixingmeans 8 may fix some of the cable bundles 6 to the movable member 4.That is, some of the cables 6 not fixed to the inside of the hollow pipemember 5 may be passed through an appropriate portion.

Although each of the cable bundles 6 in the above-described embodimentis a cable kit fixed in advance to the second cable fixing means 8corresponding to the one which is positioned closer to the base endportion of the cable bundle 6 (positioned in the opposite side to theconnector 60 a) in the first cable fixing means 7 and the second cablefixing means 8, the invention is not limited to the above configuration.The cable bundle 6 may be fixed in advance to one of the first cablefixing means 7 and the second cable fixing means 8.

EXPLANATION OF REFERENCE NUMERALS

-   -   1 ROBOT    -   2 ROTARY AXIS CABLE WIRING STRUCTURE    -   3 FIXED MEMBER (FIRST MEMBER)    -   4 MOVABLE MEMBER (SECOND MEMBER)    -   5 HOLLOW PIPE MEMBER (ROTARY AXIS PART)    -   6 CABLE BUNDLE    -   60 CABLE    -   60 a CONNECTOR    -   61 CABLE BUNDLING MEMBER    -   7 FIRST CABLE FIXING MEANS    -   8 SECOND CABLE FIXING MEANS

What is claimed is:
 1. A rotary axis cable wiring structure comprising:a first member and a second member rotatable relatively; a cylindricalrotary axis part disposed between the first member and the second memberso as to be rotatable with respect to at least one of the first memberand the second member; one or a plurality of cable bundles passed fromone of the first member and the second member to the other through therotary axis part; first cable fixing means for fixing the cable bundlesto the first member; and second cable fixing means for fixing the cablebundles to the second member, wherein each of the cable bundlesincludes: a plurality of cables; and a cable bundling member having anouter diameter smaller than an inner diameter of the rotary axis partand bundling the plurality of cables in a state where mutual relativearrangement is maintained.
 2. The rotary axis cable wiring structureaccording to claim 1, wherein with respect to each of the cables, alength from a portion bundled by the cable bundling member to aconnector provided at an end portion is longer than a length of therotary axis part in an axial direction.
 3. The rotary axis cable wiringstructure according to claim 1, wherein each of the cable bundlesincludes two of the cable bundling members at spaced positions, and theplurality of cables are disposed mutually in parallel in a sectioninterposed between the cable bundling members in a predetermined stateof the first member and the second member not rotated relatively.
 4. Therotary axis cable wiring structure according to claim 3, wherein thepredetermined state of the first member and the second member notrotated relatively corresponds to a state of the rotary axis partpositioned at a reference angle, and the rotary axis part has allowablemaximum twisting angles equal in both normal and reverse rotatingdirections from the reference angle.
 5. The rotary axis cable wiringstructure according to claim 1, wherein each of the cable bundles is acable kit fixed in advance to one of the first cable fixing means andthe second cable fixing means, the one being positioned closer to a baseend portion of each of the cable bundles.
 6. The rotary axis cablewiring structure according to claim 1, wherein a same member serves aseach of the cable bundling members.
 7. The rotary axis cable wiringstructure according to claim 1, wherein the cable bundling member is aplate member having a substantially same width as a width of each of thecable bundles, and has a structure capable of being fixed by a bolt tothe first cable fixing means or the second cable fixing means.
 8. Therotary axis cable wiring structure according to claim 1, wherein thecable bundling member is a tape member.
 9. The rotary axis cable wiringstructure according to claim 1, the rotary axis cable wiring structurefurther comprising means for identifying the cables.
 10. A robotincluding the rotary axis cable wiring structure according to claim 1.